PL226506B1 - Ventilation device - Google Patents

Abstract

The invention relates to a ventilation device provided with a heat regenerator and a moisture regenerator, composed of two regenerative blocks and reverse valves, characterized in that the two regenerative blocks (1 and V) are situated inside thin-walled channels (2 and 2') provided with gaskets (3 and 3') located on both ends of each channel. The device has four identical reverse flap valves (4, 4', 4" and 4"') interconnected in pairs into two reverse units (5 and 5') which are arranged with adapters (6 and 6') and with two horizontal partitions (7 and 7'). The device has a lower shell (8) with an edge (9) provided with splinters (10), and said edge (9) is situated on the circumference of the shell (8). The device has also an upper shell (11) with an edge (12) provided with notches (13), and said edge (12) is situated on the circumference of the shell (11). Each reverse flap valve, identically as the reverse flap valve (4) has a housing (46) with a frame (47) and a rib (48) situated on the part of the frame's circumference. Said reverse flap valve has windows (49 and 49') with rebates (50 and 50') and an inner wall (52) and an outer wall (57). The walls are in the shape of triangles. The reverse flap valve has a flap (59) provided with a roller (60) with a bushing (61) and a separable disk (63) provided with a driver (64) and a bushing (65). The driver (64) is connected to a slider (66) via a push-bar (67), additionally the slider (66) is connected to a linear actuator (69) via a spring (68). The lower shell (8) has a socket (14) for an acoustic silencer (15) and said sockets contains a bottom (15') of a fan (16). The shell has a socket (17) for an acoustic silencer (18) and sockets (22 and 22') for the reverse units (5 and 5'). The units have sealing recesses (28 and 28'). The lower shell (8) has a cavity (23) with a socket (25) for the horizontal partition (7) and a cavity (26) with a socket (25') for the horizontal partition T and it also has sockets (19 and 19') for the regenerative blocks (1 and 1'). Said sockets have recesses (27 and 27') for the gaskets (3 and 3'), furthermore the shell has a vertical partition (20) with an edge (21).

Description

Description of the invention

The subject of the invention is a ventilation device intended for use in the construction of ventilation of residential, office and public spaces.

A ventilation device with a heat recovery regenerator, consisting of two rectangular cross-section channels, is known from the European patent specification No. EP 0428948. In each of the channels there is a regeneration block made of a material with high heat capacity and an axial fan with the ability to change the direction of rotation of the rotor. Streams of cold supply air and streams of warm exhaust air flow alternately through both blocks. At regular intervals, the flow directions are reversed by changing the direction of rotation of the fan impellers activated by a sensor. Thereby, the heat from the extract air is collected in one regeneration block, while the heat stored in the other regeneration block is transferred to the supply air.

Also known from the Polish patent specification No. PL 218558 is a modular ventilation device consisting of two regenerative blocks forming a regenerative module, two four-way double flap switches modules, two separating channel modules and two fan modules. The modules are connected to each other by a panel and are enclosed in a rectangular housing.

Moreover, a modular ventilation device is known from the Polish patent application No. P.398599 consisting of two regenerator blocks forming a regenerator module, two four-way rotary switch modules, two diffuser modules, a fan module and an internal launcher module connected by a panel and enclosed in a rectangular casing, whereby the panel is also the housing cover.

The disadvantage of the previously known and used solutions of ventilation devices equipped with block regenerators is their complicated and complex structure with large dimensions. The known and described devices are mainly used in air handling units intended for ventilation of large cubature buildings. Moreover, the disadvantage of the known large-size modular devices is the large sealing surface and the complicated form of the module fittings, as well as the limited use of passive acoustic silencers.

A technical issue that requires a solution is the development of a new design of the ventilation device that allows to obtain a very high efficiency of heat recovery and high efficiency of moisture recovery, which moisture should be returned to the ventilated room. This device is to be characterized by a simple and reliable structure with a minimum number of moving parts, as well as to ensure the smallest possible sealing surfaces and should have efficient passive acoustic silencers, both for fans and other mechanical drives. Additionally, the solution of the new ventilation device is to protect it against freezing of the heat exchanging elements. In addition, the new ventilation device is to ensure a large range of decentralized ventilation by creating a slow, acceptable standards, air circulation in the ventilated room. The new design of the ventilation device is also to enable the use of water adsorbing layers on the surface of the partitions and regenerator spacers in order to increase the degree of moisture recovery. An additional objective of the solution according to the invention is to obtain the technical effect of building a device with a low electrical power per unit volume of exchanged air. Another issue that requires a solution is the development of a new design of the ventilation device, which is to enable the construction of small-size decentralized ventilation units, which are also quiet, easy to control individually, and easy to use and keep the entire device clean. In addition, the solution of the new design of the ventilation device is to enable the use of multi-parameter automatic control based on CO2, relative humidity and temperature sensors.

The ventilation device according to the invention provided with a heat and moisture regenerator is characterized in that it is equipped with two regenerative blocks and two switches, the regenerative blocks are located inside thin-walled tunnels provided with gaskets placed at both ends of the tunnels and equipped with four identical flap dampers. which are interconnected in pairs into two sets of dampers, which in turn are set up with two adapters respectively, as well as are set up with two horizontal partitions respectively, and moreover, the device has a bottom shell with an edge located on the circumference of this shell

PL 226 506 B1 and provided with splines, and has an upper shell with an edge located on the perimeter of the upper shell, provided with notches, while each flap damper has, similarly to the damper: a body with a frame and a rib located on a part of the perimeter of the frame, and also has windows with appropriately assigned rebates and includes an inner wall and an outer wall in the shape of triangles, and also has a flap equipped with a shaft with a bushing and has a detachable disc having a driver and a bushing, the driver being connected to the slider via a pusher, and the slider connected by a spring with a linear actuator, while the lower shell has a seat for a first silencer with a fan bottom and a seat for a second silencer and furthermore has one seat and a second seat for damper assemblies with a sealing recess, in addition, the lower shell is provided with a cavity with a seat for a horizontal partition and a recess with a socket m for a horizontal partition and has slots for the regeneration blocks mentioned above with recesses for the gaskets, and further includes a vertical partition with an edge, the recess having an opening in the bottom wall and the slot having a cutout in the side wall, while the side walls of the recess they approach each other in the direction of air flow, while the acoustic muffler is C-shaped and has a bottom and covers the fan housing, and the acoustic muffler is U-shaped and forms the fan inlet, while the upper shell has a seat for a third acoustic muffler with the bottom of the fan and it has a seat for a fourth acoustic silencer, and moreover, it has seats for damper assemblies with sealing recesses, as well as a recess with a seat for the first partition and a recess with a seat for a second partition, and also includes recesses for regeneration blocks with recesses for gaskets, and it is also provided with a vertical partition z edge, while the recess has a cutout in the side wall, and the seat has a cutout in the side wall, the side walls of the recess approach each other in the direction of air flow, and the third acoustic damper is C-shaped and has a bottom, and the third damper includes the fan housing, and the fourth acoustic muffler is U-shaped and constitutes an inlet to the fan.

The lower shell and the upper shell adjoin each other at their edges with their associated projections and notches, and adjoin the edges, the first silencer adjacent to the fourth silencer, and the second silencer adjacent to the third silencer, and the first horizontal partition adjacent to the sockets, while the second horizontal partition adjoins the seats, while the first grouped flaps are seated in the seats, and the second set of second dampers are seated in the seats, and the seats form a chamber in which the first regenerative block is located, and the sockets form a chamber in which the second regeneration block is located, moreover, the throttle body has a tray in which the shaft is located, and on the inner wall in the closing part of the tray there is an opening in which the shaft is located, and in the outer wall, in the closing part trough, there is an opening, in which the axis of rotation is placed, the inner wall is equipped with a positioning socket and a positioning pin, while the body, excluding the socket and spigot, is symmetrical in relation to the "P" plane, and the connection of two bodies with internal walls causes the pin to be located in one socket and locating the pin in the second seat, while the folding of the two bodies with the inner walls respectively with the seats forms a chamber in which the discs with pushers and the pivot axis support are located, the driver being connected to the slider by a pusher while the second driver is connected with the slider through the second pusher, while the flap in extreme positions sticks to the rebates. The detachable disc is connected to the shaft via a spline located in the bore, while the length "k" of the shaft is less by the value "x" than the distance "h" between the inner and outer walls, the outer wall having a socket in which a fitting with the axis of rotation is located in the opening, while the inner wall is provided with a socket in which the support for the axis of rotation is located, and in which the first adapter has a monolithic block and the second adapter has another monolithic block, while in linear actuators are attached to monolithic blocks.

Ventilation device according to the invention in an embodiment, in which the first edge along its length has a longitudinal circumferential internal projection and the second edge along its length has a longitudinal circumferential internal groove or vice versa, while the detachable disc of the first damper is in the form of a gear wheel, and its pusher is in the form of a rack, while

The detachable disc of the second throttle is in the form of a toothed wheel, and its pusher is in the form of a rack, while both racks are connected to each other by a slider, and the drivers are connected to the slider by a horizontal U-shaped elastic connector, the spring connector in extreme positions closes the damper with its own elasticity. On the other hand, the slider is connected to the connecting rod via a pin, and the connecting rod is connected to the pin on the crank crank, with the size of the crank and the length of the connecting rod selected so that the flaps rotate by 90 ° between the extreme positions, while the crank rotates by the angle of 180 ° between the extreme positions, and also in extreme positions, the pivots and the crank rotation axis lie on one straight line, and the crank rotation axis is on the motor axis, thanks to which the flap drive unit becomes self-locking, and in addition, the lower shell and the upper shell are made are preferably foamed material.

The solution according to the invention is distinguished by the possibility of constructing ventilation devices with high heat recovery efficiency and high humidity recovery efficiency, which moisture is returned to the ventilated room. Another advantage of the solution according to the invention is the simple structure and the limited number of moving parts that support all functions of the device. In addition, the device is characterized by a small sealing area and a simple structure of moldings creating connections between its main functional elements, such as regenerative blocks, dampers and fans. Another advantage of the device is the use of numerous passive acoustic silencers for fans and air streams as well as the use of acoustic silencers in the form of monolithic adapters and springs in the damper blade drive unit, ensuring their quiet operation. In addition, the device is so constructed that it effectively eliminates freezing of heat transfer elements. An additional advantage of the ventilation device is the possibility of obtaining a large range of decentralized ventilation by creating slow, acceptable standards, air circulation in the ventilated room. A further advantage of the device according to the invention is the possibility of using water-adsorbing layers on the surface of the regenerator baffles and spacers in order to increase the degree of moisture recovery. Another advantage of the solution of the device according to the invention is the achievement of the technical effect which enables the construction of ventilation devices with low electrical power per unit of the volume of exchanged air. An additional advantage of the device is the possibility of ventilation without heat recovery. Yet another advantage of the ventilation device solution according to the invention is the possibility of building small-size decentralized ventilation units, which allow for individual control, easy to use and clean the entire device, and are characterized by very quiet operation and effective acoustic suppression of noise coming from outside the building. In addition, the entire structure of the new ventilation device allows the use of multi-parameter automatic control based on CO2, relative humidity and temperature sensors.

Figure 1 shows an axonometric view of the device assembly, Figure 2 - a scattered axonometric view of the device assembly, Figure 3 - a scattered axonometric view of the device assembly from above with the upper shell removed 11, Figure 4. - a scattered axonometric view of the device assembly from the bottom with the lower shell 8 removed, Fig. 5 - an axonometric view of the device assembly from the top with the upper shell 11 removed, Fig. 6 - an axonometric view of the device assembly from the bottom with the lower shell 8 removed, Fig. 7 - Fig. 8 is an axonometric view of the upper shell 8 from the top, Fig. 8 - an axonometric view of the upper shell 11 from the bottom, Fig. 9 - a dispersed axonometric view of the throttle 4 from the side of the inner wall 52, Fig. 10 - an axonometric dispersed view of the throttle assembly 5 from the side of the inner wall 52 , fig. 11 - an axonometric view of the throttle 4 and the throttle 4 'from the side of the internal walls 52 and 52' with protruding disks 63 and 63 ', Fig. 12 - a scattered axonometric view of the damper unit 5 from the side of the outer wall 57 with the partition 7 and the adapter 6, Fig. 13 - an axonometric scattered view of the flaps 59 and 59' of the damper assembly 5 with the remaining elements of the drive, Fig. . 14 - an axonometric dispersed view of the damper assembly 5 in the embodiment variant with the bodies removed and with exposed gears, racks and slider, Fig. 15 - an axonometric dispersed view of the throttle assembly 5 in the embodiment variant with the bodies removed and exposed disks, elastic connector and slider, Fig. 16 is a scattered axonometric view of the throttle assembly 5 in the embodiment with the bodies removed and exposed discs, pushers, slider, connecting rod and crank; Fig. 17 is a cross-sectional view of the device in an embodiment along line AA in Fig. 1, and Fig. 18 shows the view of the throttle 5 from the side of the flap 59.

PL 226 506 B1

The ventilation device is built of two regenerative blocks 1 and 1 'located inside thin-walled tunnels 2 and 2', provided with gaskets 3 and 3 'located at both ends of the tunnels, and has four identical flaps 4, 4', 4 and 4 '' connected mutually in pairs into damper assemblies 5 and 5 ', and the damper assemblies are assembled with adapter 6 and 6' and a horizontal partition 7 and 7 ', respectively, and adapters 6 and 6' have monolithic blocks 6 and 6 ", respectively. In addition, the device has a lower shell 8 with an edge 9 provided with protrusions 10 on the circumference of the shell 8 and an upper shell 11 with an edge 12 provided with notches 13 located on the circumference of the shell 11. The lower shell 8 at one end has a seat 14 in which a damper is located. acoustic 15 with a bottom 15 'of a fan 16, and at the other end it has a seat 17 with an acoustic muffler 18. The lower shell 8 in the central part has seats 19 and 19' for regeneration blocks 1 and 1 'separated by a vertical partition 20 with an edge 21 and has adjacent with 19 and 19 'seats, 22 and 22' seats for 5 and 5 'damper assemblies. In turn, between the seat 22 and the seat 14 there is a recess 23 with an opening 24 and a seat 25 for a horizontal partition 7, and between the seat 22 'and the seat 17 there is a recess 26 with a seat 25' for a horizontal partition 7 '. Furthermore, seat 19 has recesses 27 for gaskets 3, seat 19 'has gasket recesses 27' for gaskets 3 ', seat 22 has sealing recess 28 and seat 22' has sealing recess 28 'and seat 14 has recess 29. The upper shell 11 has a seat 30 at one end in which an acoustic damper 31 is located with a bottom 31 'of a fan 32, and at the other end it has a seat 33 with a sound absorber 34. The upper shell 11 in the central part has slots 35 and 35' for blocks regenerative 1 and 1 'partitioned by a vertical partition 36 with an edge 37 and has slots 38 and 38' adjacent to the seats 35 and 35 'for the damper assemblies 5 and 5'. In turn, between the seat 33 and the seat 38 there is a recess 39 with a seat 40 for a horizontal partition 7, and between the seat 38 'and the seat 30 there is a recess 41 with a seat 40' for a horizontal partition 7 'with a cutout 42. Moreover, the seat 35 has recesses 43 for gaskets 3, and seat 35 'has recesses 43' for gaskets 3 ', seat 38 has sealing recess 44, seat 38' has sealing recess 44 'and seat 30 has recess 45.

In a variant of the device embodiment, the edge 9 of the shell 8 along its length has a longitudinal circumferential internal groove 9 ', and the edge 12 of the shell 11 along its length has a longitudinal circumferential internal groove 12'.

Lower shell 8 and upper shell 11 adjoin each other by edges 9 and 12 with associated protrusions 10 and notches 13, and adjoin edges 21 and 37, the sound absorber 15 being adjacent to the sound absorber 34 constituting the inlet to the fan 16, and the sound absorber 31 in turn. adjacent to the sound absorber 18 constituting an inlet to fan 32, the horizontal baffle 7 adjoins the seats 25 and 40, respectively, separating the recesses 23 and 39, and the horizontal baffle 7 'adjoining the seats 25' and 40 'separating the recesses 26 and 41, in turn the assembly of dampers 5 is seated in seats 22 and 38, respectively, while the set of dampers 5 'is seated in seats 22' and 38 ', and seats 19 and 35 in the assembly form a chamber in which a tunnel 2 with a regeneration block 1 is located, while the seats 19 'and 35' in the assembly form a chamber in which the tunnel 2 'with the regeneration block 1' is located. The opening 24 is the inlet of air from the ventilated room to the device, and the cutout 29, after folding the shells 8 and 11, is the outlet of air from the device to the ventilated room. In turn, the cutout 42, after the collapsed shells 8 and 11, constitute the inlet of external air to the device, while the cutout 45, after the collapsed shells 8 and 11, constitute the outlet of air from the device outside the room. In turn, the flap damper 4 has a body 46, and the flap damper 4 'has a body 46', and the frame 47 of the body 46 has a rib 48 located on a part of the perimeter of the frame, and further has windows 49 and 49 'with rebates 50 and 50', wherein the surfaces of the windows converge and merge into the tray 51 and have an inner wall 52 with a positioning socket 53 and a positioning pin 54, and a socket 55 and a socket 56, and an outer wall 57 with a socket 58, the inner wall 52 and the wall the outer part 57 is shaped like triangles. In turn, the flap damper 4 'has a tray 51' and has an inner wall 52 'with a positioning seat 53' and a positioning pin 54 ', and has a seat 55' and a seat 56 ', and has a shaft 60' of the flap 59 ', and also includes a molding 74 'with a rotation axis of 75'. In addition, the throttle 4 is provided with a tray 51, and the throttle 4 '' is provided with a tray 51. Moreover, the flap damper 4 has a hatch 59 with a shaft 60 located in the tray 51, and the shaft 60 has a bush 61 and is connected by a spline 62 to a detachable disc 63 comprising a driver 64 and a bush 65, the driver 64 being connected to the slider 66

The pusher 67 is connected by means of a pusher 67, and the slider 66 is connected via a spring 68 to the linear actuator 69. The pusher 67 has two holes 70 and 70 ', and a driver 64 is located in the hole 70, and a pin is located in the hole 70'. 71 of the slider 66. Similarly, the throttle 4 'has a disc 63' equipped with a driver 64 ', and the pusher 67' connects the driver 64 'to the pin 71' of the slider 66. In the socket 55 there is a bracket 72 with the axis of rotation 73, and in the socket 56 there is there is a disc 63 with a pusher 67, and in turn in the socket 58 a molding 74 with an axis of rotation 75 is placed. In the inner wall 52 in the part closing the tray 51 there is an opening 76, in which the connection spline 62 is located, and in the outer wall 57 in a part closing the tray 51 in the seat 58 there is an opening 77, in which the axis of rotation 75 is located. On the axes 73 and 75, through the bushings 61 and 65, a damper flap 59 is suspended 4. Dampers 4 and 4 'bad With internal walls 52 and 52 ', respectively, they form a set of dampers 5 connected by trays 51 and 51' with the adapter 6 and with a partition 7, while dampers 4 and 4 '' composed by internal walls 52 and 52 '', respectively, form a set of dampers 5 'connected with appropriate 51 and 51 '' channels with a 6 'adapter and a 7' partition. The throttle seat 56 of the throttle 4, assembled with the throttle seat 56 '4', form a chamber 78 in which the discs 63 of the throttle 4 and 63 'and the throttle 4', and the followers 67 and 67 ', respectively, as well as the bracket 72 with the axis of rotation 73 are located. In one embodiment, discs 63 and 63 'are gears 79 and 79', respectively, and followers 67 and 67 'are gears 80 and 80', respectively, engaged with gears 79 and 79 ', respectively, and connected to slide 66. In another embodiment, drivers 64 and 64 'are connected to the slider 66 via a spring link 81. In a further embodiment, the slider 66' is connected to the connecting rod 82 by a pin 83, and the connecting rod 82 is connected to a pin 84 on crank crank 85, the axis of which is in turn the axis of the engine. 86. The flaps 59 and 59 'rotate 90 ° between locks, while the crank makes a turn 180 ° between locks. The ventilation device according to the invention with a heat and moisture regenerator is characterized by a cyclic operation. Streams of cold air supplied to the room and streams of warm air removed from the room flow alternately through two regeneration blocks. At regular intervals, the flow directions are reversed by changing the position of the flaps. The fan 16 draws air through the silencer 34 from the space above partition 7 and blows into the ventilated room through the cutout 29, while the fan 32 draws air through the silencer 18 from the space below partition 7 'and blows outside the room through the cutout 45. Air from inside the ventilated room is taken through opening 24 into the space below partition 7, and external air is taken through opening 42 into the space above partition 7 '. Depending on the position of the 4 and 4 '' as well as 4 '' and 4 '' damper flaps, the air flows through the regeneration blocks 1 and 1 'alternately in opposite directions. In the operating cycle of the device, three states are distinguished: work state I, work transition state II and work state III. In state I, all the damper blades are in their extreme positions and so the damper blade 4 is raised, the damper blade 4 'is lowered, while the damper blade 4 is raised and the damper blade 4' 'is lowered. The warm air from the room then flows through the regeneration block 1 and heats it. The outside air, on the other hand, flows through the regeneration block 1 'taking from it the heat deposited here in the previous cycle. In transition state II, all the damper flaps move simultaneously to the opposite extreme position. In state III, the throttle valve 4 is lowered, the throttle valve 4 'is raised, while the throttle valve 4 is down, and the throttle valve 4 "is raised. Then warm air from the room flows through the cooled regeneration block 1 ', depositing heat therein. The outside air flows through the heated regeneration block 1, taking heat therefrom. Stopping the damper flaps in one of the extreme positions allows the device to be used for ventilation without heat recovery. The device is powered by electricity from the network. As an alternative source of energy to power the device, a photovoltaic cell panel and a battery are preferably used, the photovoltaic cell panel being preferably located on the exterior windowsill of the building or on its facade wall. The switching frequency of the damper flaps is automatically changed depending on the ventilation capacity and the temperature difference between the inside of the ventilated room and the outside atmospheric air. The ventilation capacity is step-adjusted depending on the CO2 content in the ventilated room. The device additionally has a CO2 level sensor located outside its housing in a place representative for measurement purposes. The CO2 level sensor communicates with the device via electromagnetic waves.

Claims (22)

1. Ventilation device equipped with a heat and moisture regenerator and composed of two regenerative blocks and two switches, characterized in that the regeneration blocks (1 and 1 ') are situated inside thin-walled tunnels (2 and 2') provided with gaskets (3 and 3). ') located at both ends of the tunnels and equipped with four identical butterfly valves (4, 4', 4 and 4 ''), which are interconnected in pairs into two sets of dampers (5 and 5 '), which in turn are arranged respectively with two adapters (6 and 6 '), as well as with two horizontal partitions (7 and 7'), respectively, and moreover, the device has a bottom shell (8) with an edge (9) located on the circumference of the shell (8) and provided with into the projections (10) and has an upper shell (11) with an edge (12) located on the circumference of the upper shell (11) provided with notches (13), while each flap damper has, similarly to the damper (4) a body (46) with a frame (47) and with a rib (48) located on part of the circumference of ra we, and also has windows (49 and 49 ') with appropriately assigned rebates (50 and 50') and has an inner wall (52) and an outer wall (57) in the shape of triangles, and also has a hatch (59) equipped with a shaft ( 60) with the bushing (61) and has a detachable disc (63) having a driver (64) and a bush (65), the driver (64) being connected to the slide (66) via a pusher (67) and the slide (66) it is connected via a spring (68) to the linear actuator (69). 2. The ventilation device according to claim 1, The lower shell (8) has a seat (14) for an acoustic damper (15) with a bottom (15 ') of a fan (16) and a seat (17) for an acoustic damper (18), and also has seats ( 22) and seats (22 ') for damper assemblies (5 and 5') respectively with a sealing recess (28 and 28 '), respectively, while the lower shell (8) is provided with a recess (23) with a baffle seat (25) horizontal (7) and a recess (26) with a seat (25 ') for a horizontal partition (7'), and also has seats (19 and 19 ') for regeneration blocks (1 and 1') with recesses (27 and 27), respectively ') for gaskets (3 and 3'), respectively, and also has a vertical partition (20) provided with an edge (21). 3. The ventilation device according to claim 1 The recess (23) as claimed in claim 2, characterized in that the recess (23) has an opening (24) in the bottom wall and the seat (14) has a cutout (29) in the side wall, while the side walls of the recess (26) approximate each other in the direction of air flow, while the acoustic muffler (15) is C-shaped with a bottom (15 ') and includes the fan housing (16), and the acoustic muffler (18) is U-shaped and forms an inlet to the fan (32). 4. The ventilation device according to claim 1 3. The shell as claimed in claim 1, 2 or 3, characterized in that the upper shell (11) has a seat (30) for an acoustic muffler (31) with a bottom (31 ') of a fan (32) and a seat (33) for an acoustic muffler (34), and moreover, it has seats (38 and 38 ') for the damper assemblies (5 and 5') respectively with sealing recesses (44 and 44 '), respectively, and is provided with a recess (39) with a seat (40) for the partition (7) and into a recess (41) with a seat (40 ') for the baffle (7'), and further includes seats (35 and 35 ') for regeneration blocks (1 and 1'), respectively, with recesses (43 and 43 ') for gaskets ( 3 and 3 ') and is furthermore provided with a vertical partition (36) with an edge (37). 5. The ventilation device according to claim 1 The recess (41) as claimed in claim 4, wherein the recess (41) has a cutout (42) in the side wall and the seat (30) has a cutout (45) located in the side wall, while the side walls of the recess (39) approximate each other in the direction of air flow. and the acoustic muffler (31) is C-shaped and has a bottom (31 '), and the muffler (31) includes the fan housing (32), and the acoustic muffler (34) is U-shaped and forms an inlet to the fan ( 16). 6. The ventilation device according to claim 1 3. The method of claim 1 or 2, characterized in that the lower shell (8) and the upper shell (11) adjoin each other by the edges (9) and (12) with associated protrusions (10) and notches (13) and adjoin with the edges (21 and 37). ), the acoustic silencer (15) adjacent to the acoustic silencer (34), and the acoustic silencer (18) adjacent to the acoustic silencer (31), and the horizontal barrier (7) adjoining the sockets (25 and 40), and the horizontal barrier (7 ') adjoins the seats (25' and 40 '), while the flaps (4 and 4') connected to the set (5) are seated in the seats (22 and 38), and connected to the set (5 ') ) flap dampers (4 and 4 ") are mounted in seats (22 'and 38'), And the seats (19 and 35) form a chamber in which the regeneration block (1) is located, and the seats (19 'and 35') form a chamber in which the regeneration block (1 ') is located. 7. The ventilation device according to claim 1 The throttle body (4) as claimed in claim 1, characterized in that the body (46) of the throttle (4) has a tray (51) in which the shaft (60) is located. 8. The ventilation device according to claim 1, The method of claim 1, characterized in that on the inner wall (52), in the tray closing part (51), there is an opening (76) in which the connection spline (62) is located, and in the outer wall (57) in the tray closing part. (51) there is a hole (77) in which the axis of rotation (75) is located. 9. The ventilation device according to claim 1 The device of claim 1, characterized in that the inner wall (52) is provided with a positioning seat (53) and a positioning pin (54). 10. The ventilation device according to claim 1 6. The method of claim 1 or 7, characterized in that the body (46), excluding the seat (53) and the spigot (54), is symmetrical with respect to the "P" plane. 11. The ventilation device according to claim 1. The plug as claimed in claim 1 or 7, characterized in that the connection of the body (46) and the body (46 ') with internal walls causes the position of the pin (54) in the seat (53') and the position of the pin (54 ') in the seat (53). 12. The ventilation device according to claim 1. A chamber according to claim 1 or 10, characterized in that the assembly of the two bodies (46 and 46 ') with the inner walls (52 and 52') with the seats (56 and 56 '), respectively, forms a chamber (78) in which the discs (63 and 63') are located. ) with the followers (67 and 67 ') and the pivot support (72) (73), the driver (64) being connected to the slider (66) via the follower (67), while the driver (64') is connected to the slider (66) through the follower (67 '). 13. The ventilation device according to claim 1, 3. The flap (59) as claimed in claim 1, in its extreme positions, rests on the rebates (50 and 50 '). 14. The ventilation device according to claim 1. The method of claim 1, characterized in that the detachable disc (63) is connected to the shaft (60) via a spline (62) which is located in the bore (76), while the length "k" of the shaft (60) is smaller by the value "x "From the distance" h "between the wall (52) and the wall (57). 15. The ventilation device according to claim 1, A device as claimed in claim 1, characterized in that the outer wall (57) has a seat (58) in which a shaped piece (74) is positioned with the axis of rotation (75) located in the opening (77). 16. The ventilation device according to claim 1, The device of claim 1, characterized in that the inner wall (52) is provided with a seat (55) in which a pivot axis support (72) (73) is located. 17. The ventilation device according to claim 1, 1, characterized in that the adapter (6) has a monolithic block (6), and the adapter (6 ') has a monolithic block (6 ""), while linear actuators are mounted in monolithic blocks (6 and 6 ") respectively as (69 and 69 '). 18. The ventilation device according to claim 1, A method according to claim 1, characterized in that, in an embodiment, the edge (9) has a longitudinal circumferential inner groove (9 ') along its length and the edge (12) has a longitudinal circumferential inner groove (12') along its length or vice versa. . 19. The ventilation device according to claim 1 The method of claim 1, characterized in that in the embodiment the detachable throttle disc (4) is in the form of a toothed wheel (79) and its pusher is in the form of a rack (80), while the detachable throttle disc (4 ') is in the form of a toothed wheel (79'), and its pusher is in the form of a rack (80 '), while the racks (80 and 80') are connected by a slider (66). 20. A ventilation device according to claim 1. The method of claim 1, characterized in that, in the embodiment variant, the drivers (64 and 64 ') are connected to the slider (66) by an elastic connector (81) in the shape of a horizontal "U" letter, while the spring connector (81) closes the damper in extreme positions by its own force elasticity. 21. A ventilation device according to claim 1. The rod according to claim 1, characterized in that in an embodiment the slider (66 ') is connected to the connecting rod (82) via a pin (83) and the connecting rod (82) is connected to the pin (84) on the crank crank (85), the size of which is the cranks (85) and the length of the connecting rod (82) are selected such that the flaps (59 and 59 ') rotate 90 ° between their extreme positions, while the crank (85) makes a rotation 180 ° between their extreme positions. and in the extreme positions, the pins (83 and 84) and the axis of rotation of the crank (85) lie on one straight line, and the axis of rotation of the crank (85) is on the axis of the motor (86), whereby the flap drive assembly becomes self-locking. 22. A ventilation device as claimed in claim 1, The method of claim 1, characterized in that the lower shell (8) and the upper shell (11) are preferably made of a foamed material.